Still picture recorder for television receivers



2,680,148 STILL PICTURE RECORDER FOR TELEVISION RECEIVERS Filed Oct. 29, 1949 June 1'. 1 4 E. s. PURINGTON ET AL 4 Sheets-Sheet 2 v 3nventots ELLISON 5. PURINGTON,

. 9 JOHN HA YS HAMMOND, JR.

Jun 1. as. PURINGTON ET'AL 2,680,143

STILL PICTUR RECORDER FOR TELEVISION RECEIVERS iled Oct. 29, 1949 4 sheets sh eet 3 3nven tors ELLISON s. FURlNG-TON,

73 JOHN HAYS HAMMOND, JR.

ttomeg um 1:, 5954 E. s. PURINGTON ET AL 2,580,145

STILL PICTURE RECORDER FOR TELEVISION RECEIVERS Filed Oct. 29, 1949 4 Sheets-Sheet 4 SHUTTER LIFTER Q 0 2 31 1 WU.

I I2 75 2L4, o 1 I74 noi 1 IIOa 1 70 we IL 4- 1\ SECONDARY I60 "l6l \L *1 37 I62, MTNUAL. 9

80 U RELAY I'- l E 5 44 Bnn'entors L ELLlSON S. PURINGTON, 83

H JO H N HAYS HA M M o N D u R.

W (Ittorneg Patented June 1, 1954 STILL PICTURE REC-ORDER FOR TELEVISION RECEIVERS Ellison S. Purington and John Hays Hammond, Jr., Gloucester, Mass. said Purington assignor to said Hammond, Jr.

Application October 29, 1949, Serial No. 124,418

1 5 Claims.

This invention relates to the recording of pictures produced by television transmission upon a television receiver screen.

The invention provides means in cooperation with a standard television receiver for setting up a camera system and operating the camera shutter in response to depressing a push button, whereby a picture may be properly recorded not later than one second after a decision has been made to make the record. The construction is such that normally the camera is in a folded condition so that there is no interference with the normal viewing of the television screen.

The invention further provides means whereby the recording may be controlled from a remote location, and more specifically from the transmitter studio. In this manner special picture in formation known to be of permanent interest to the television receiver owner may be flashed, requiring a video transmission time of less than half a second. Such recordable information might include weather maps, recipes, emergency instructions in times of disaster, baseball scores. facsimiles of box tops, finger prints and photographs for police purposes, and the like.

The invention provides further a system of remote control signalling suitable for operating the camera whereby it will not respond improperly to signals normally passing from the transmitter to the receiver.

The invention also consists in certain new and original features of construction and combination of parts hereinafter set forth and claimed. The nature of the invention will be better understood by referring to the following description, taken in connection with the accompanying drawings forming a part thereof in which Fig. 1 is a schematic diagram illustrating the general arrangement of a receiver embodying the invention;

Fig. 2 is a side elevation partly in section of the camera and control unit;

Fig. 3 is an end elevation partly in section looking at the lifter end of the mechanism,

Fig. 4 is a top plan view of the camera and lifting mechanism Fig. 5 is a schematic diagram showing a systerm for operating the camera manually from a push button located near the camera, or remotely in accordance with the operation of a distant control such as at the transmitter.

Like reference characters denote like parts in the several figures of the drawings.

In the following description, parts will be identified by specific names for convenience, but I 2 they are intended to be generic in their application to similar parts.

Referring to the drawings and more particularly to Fig. 1, the receiving system includes a television receiver H), which may be of standard commercial construction. This is provided with terminals H connected to a receiving antenna not shown, and produces a television picture designated by the double ended arrow upon the screen of the kinescope 12, when the controls l3 are suitably adjusted and the set powerized. Terminals it are connected in parallel with the leads E la from the audio output transformer M to the loud speaker LS so that special signals sent through the audio system of the television transmitter and receiver may be used to cause a picture to be taken automatically, in a manner to be described. The television receiver is mounted on the top it of a table or cabinet which may house other equipment shown in this figure.

The camera I? for taking and recording a picture shown in more detail in Figs. 2, 3, 4, projects upwardly through a hole in the table top 5 6, and includes a mirror frame I8 mounted to rotate about a hinge pin is in such a manner that it may be elevated from the normal horizontal position to a position at an angle of approximately :5 degrees with the horizontal as indicated by dash lines to intercept the picture rays and reflect them downwardly to the camera lens. The mirror I8 is elevated electrically by means of a solenoid of standard construction including a coil 20 within a solenoid frame not shown, which draws up a plunger 2! when the coil 293 is energized. The lower part of the plunger is connected by riser bars 22, 23 and a hinge 24 to the mirror frame it. These parts I8 to 24 inclusive constitute the camera lid assembly which as a unit is mounted from the camera chassis 25. For simplicity the mirror on the underside of the mirror frame and various other parts are not shown in detail.

In addition to the mirror, the optical system of the camera includes a lens 26 complete with shutter, lens and iris mounted with its axis vertical as shown so that when the mirror frame iii is raised to a 45 angle, the central ray from the picture AOB on the television screen which comes to the center of the aperture of the lens will travel horizontally to the right and vertically downward. Below the lens 26 is the dark chamber .i'i associated with the upper or optical part of the camera, and a detachable dark chamber 23 associated with the lower or photo-chemical part of the camera. When the mirror frame is raised to 45 and the shutter is opened, the picture AOB produces an image A'O'B within the chamber 20, and the choice of parts and dimension is such that this occurs in the plane of a record ing surface, such as the negative of a standard commercial film not shown. Since the nature of the recording material does not constitute a part of the present invention, the equipment in and associated with the chamber 28 is not shown or described in detail.

For actuating the shutter of lens system 25, a solenoid type actuator is provided with coil 29, plunger 00, the latter being hinged by pin st to a lever 32 turning on a hinge pin 33 at the lower end. The upper end of the lever 32 projects up through the camera chassis and is connected by a coupling spring 34 to the operating lever of the shutter, not shown. It will be understood that the shutter is of the single motion type so that one lever associated with the shutter serves to cock and to trip the shutter mechanism. It will be understood that the shutter is adjusted for instantaneous exposure of duration such as A or 1A5 second, and that this will start while the plunger of the shutter solenoid is being drawn in. The lens system, upper dark chamber and shutter solenoid are all suitably supported from the camera chassis.

With this arrangement a picture may be taken by energizing winding 20 of the lifter solenoid,

causing the mirror to be elevated to 45 degree position, and subsequently energizing winding 29 of the shutter solenoid to operate the shutter mechanism, forming the latent picture AOB' on the recording surface in lower dark chamber 20. After these operations, the currents in the solenoids may be dropped to zero, whereupon the mirror frame is restored to normal horizontal position by the force of gravity, and the shutter solenoid plunger is pulled out by the action of the spring 34 in connection with the spring system within the shutter. This restoring action is also sufficient to restore the shutter mechanism self to normal so that it may be subsequently opened during a later operation of the shutter solenoid. Care must be taken so that there is little frictional drag associated with the lever 32, its hinges or the plunger 30.

The camera ll is connected by a control line 35 to the controller 36 shown in block diagram, but including a push button 37, a power source, and timing means. These are arranged so that pushing the button operates first the lifter mechanism and then the shutter mechanism. In case several exposures are to be made in rapid suc cession, the control may be such that the shutter solenoid operates and releases several times while the mirror is in the lifted position. For such multiple operation, the controller mechanism also should serve to change the recording surface where the image AO'B' is formed on successive exposure surfaces.

The controller 30 is provided with three terminals 38, 39, 40 suitably connected to the push button 3'! so that the control operation may also be executed from a remote location or in the instance shown by a suitable audio signal applied from terminals 55 of the television receiver. Thus the controller circuits may be so organized that normally terminal 30 is connected to terminal 00, that the shutter solenoid may be ca sod to operate say 0.8 second after the external connection between 30 and 50 is broken, and that the lifter solenoid may be caused to be lifted and to be at rest in lifted position 0.5 second after iii) external connection has been made between terminals 3S and 30. Details of a suitable camera and controller mechanism for this purpose are shown in Figs. 2, 3, 4, 5, together with additional features which for clearness have not been incorporated in the general diagram of Fig. 1.

For operating the controller from external connections at terminals 33, 39, 40, in response to a suitable signal at the special audio terminals, a selective audio relay system is used. In the present instance it is assumed that the control will be exercised by a high frequency tone such 7000 C. P. S. coming from the transmitter after a preparatory tone say of 6500 C. P. S. value. Thus the entire audio tone could be of four seconds duration, that is 6500 for two seconds followed by 7000 for two seconds, with the camera arranged to take the picture being transmitted between 0.8 and 1.2 second after the change from 6500 to 7000 cycles. The circuits for operating the controller may be such as provided by the audio AVC system 4!, discriminator 42, D. C. amplifier 03 and relay 44 of Fig. 1. These circuits may be referred to as the selector circuit. The purpose of the AVG system is to provide the discriminator with a signal of 7000 C. P. S. of suitable strength over a wide range of voltage which may occur at the terminals I5. The discriminator is for the purpose of operating the D. C. amplifier 43 and relay 44 in response to a control signal very closely in the vicinity of the nominal value of 7000 C. P. S. It further provides that the operation will not take place when the 7000 C. P. S. is present as a harmonic overtone of speech or musical signals, but will take place only when the 7000 cycle tone is clearly that which is intended to operate the camera.

The audio AVC system may be of any well known construction. Thus the output terminals :5 may be operatively connected to terminals 45 of the AVG circuit to drive the control grid of a remote cutofi pentode with resistor plate feed in the output circuit. The output of this pentode may be coupled to the output terminals 40, and also coupled to drive a rectifier, the D. C. output of which is inserted back into the grid circuit of the pentode in such a manner as to increase the grid bias. Preferably the AVG should be of the delayed type whereby there is no rectified output and consequently no reduction of gain unless the input signal exceeds a suitable threshold value. The time constant may be of the order of 0.5 second such that equilibrium is fairly completely established in 2.0 seconds corresponding to the duration of the 6500 cycle preliminary signal. This system should pass all frequencies say from 500 to 8000 C. P. 53., so that the discriminator may be energized not only by the 7000 C. P. S. control signal, but also by 3500, 2333, 1750, 1400 C. P. S. etc. which may be the fundamentals of a 7000 C. P. S. tone component which is not desired to operate the system.

One of the output terminals 40 of the AVG system is connected to ground line 41, and the other to a conventional amplifier stage 48, where the signals are amplified and impressed through coupling capacitor 00 and through selective circuits onto the grids of two rectifier driver triodes and Si. For this purpose, the output terminal 52 of capacitor 09 is connected through resistor 53 to the grid of triode 50, which is connected to ground line 47 through inductor 54 paralleled by capacitor 55. The circuit 54, 55 is tuned to 7000 C. P. S., and the connections are were such that tube 50 wil be driv n mo strongly when the voltage between terminal 52 and ground line 41 is about 7000 CJP, On the other hand,

for driving the grid of triode 5f, the terminal 52 is connected th ough'inductor'et' paralleled by capacitor 51 to one end of a potentiometer 58, the other end of which is connected to ground and the adjustable tap of which is connected to the'grid of triode Hi. The circuit 56, 51 is also timed to 7000 cycles, but the connections are such that tube 5i will be driven most strongly when the voltage between terminal 52 and ground line 41 is not 7000 cycles. Thus for example, with both tubes 50 and 5| driven from the com mon source, such as the voltage between termina152 and ground line 41, the constants of the circuitmight be chosen such that tubes 50 and 5| are equally driven both at 6500 and 7600 C. P. with tube 50 driven more strongly between these values, anl tube 5| driven more strongly outside'those values. The two triodes 50, 5| 'are of like construction; with cathodes joined together and connected to ground line e1 through cathode resistor 59 paralleled by capacitor 60; with the plates connected through equal output resistors Bi and 62 to equal high voltage sources H-V; with the plates also connected through equal capacitors 63, 84 and equal resistors 55 and 66 to ground line 4?. However the junction of capacitor 63 and resistor E5 is connected to the anode of a rectifier '5, and the junction of capacitor 64 and resistor 50 is connected to the cathode of a rectifier 68, these rectifiers being of like characteristics. The cathode of rectifier 61 and anode of rectifier 60 are connected to ground line 41 through equal resistors 69, 'llijre'spectively shunted by capacitors H, 12, and through equal resistors '53 and 14 respectively to a common output terminal marked DC, which is bypassed to ground by capacitor 15. The directions of D. C. components of rectified currents in resistors 89 and 10 are indicated by arrows, and the connections are such that signal on the grid of triode 50 tends to make the output point DC positive, and signal on the grid of triode tends to make it negative. In the absence of signal, the output terminal is at ground potential, and is conductively connected to ground through the resistors 13, 74, E8 and'lll. The

discriminator terminal DC is directly connected to the grid of a D. C'. amplifier or relay tube E6, the cathode of which is connected to ground through variable resistor T1, and also through resistor 18 to a source '19 of high voltage, which source 19 is also connected through winding 3 of relay 44 to the plate of triode 16. The relay 44 has an armature 8i normally held open by a spring 82, with a back contact 83 connected to terminal 40 ofthe'controller 36, a frontcontact 84 connected to theterminal' 38 of thecontroller, "and the armature itself connected to terminal 391" Ad justments of resistor I! are such' that when there is no A. C. voltage across terminals 55 of the receiver, the relay current is insufficient to lift the armature. Thus for example the no signal relay winding current may be 1 ma; the relay may pull in at 5 ma, and drop out and stay out when the current reduces below 3 ma. Thus the relay upon closing due to suflicient D. C. voltage at terminal DC will cause the camera I? to function just as though the push button 33' were depressed, and'upon opening due to insufiicient D. C. voltage will reset the camera just as though thefpu'shfbutton 3'l.'}were released.

Speech, and musical signals rarely, have a, fun:

damental of frequency more than 5000 cycles, and the fundamental when high is usually much stronger than the harmonics. Therefore 7000 cycle tones due to music or speech will be accompanied by stronger fundamentals which cause the voltage of terminal DC to go negative in spite of'the presence of the 7000 cycle component It is clear that the features of the selective system provide for operation of the relay 44 only when the transmitted signal is correct as to frequency within a few percent of the nominal value, and only when the signal frequency is transmitted as a fundamental and not as a harmonic of speech or musical fundamentals. This; gives the system sufficient selectivity and freedom from spurious operations on protected commercial radio channels, so that only in extremely rare cases will the system operate when not in: tended;

Although some of the new and usefu1 features of the invention are shown in Fig. 1, there are other, important features of the camera mecha nism with special reference to Figs. 2, 3, 4. spa cifically it has been found desirable to use a moving system for the mirror which is nearly in dynamic balance, so as to reduce the amount of torque which must be applied to lift the mirror from a horizontal to the operating condition. Although it is possible to counterbalance the mirror system by weights, it has been found practicable to use a spring system for this purpose.

Furthermore it has been found desirable to provide for applying an especially high torque at the start of the mirror throw, and a much lesser torque toward the end of the throw, so that the mirror may rise in the shortest possible time without excessive vibration about the point of equilibrium as the solenoid comes to rest. This may be accomplished by control of the current value in the lifter solenoid coil. This maybe done in a number of ways, but in the present iristance it has proven satisfactory to. provide a double pole double throw switch which is actuated during the rise of the mirror to decrease the voltage on the lifter solenoid after the ini tial surge of. current. It has been found practical and effective to operate this switch from the risers. of the mechanism so that the change of current willalways occurata proper point in the lifter operation.

The chassis 25 is a one piece sheet metal stamping formed in inverted U shape, with flat top beneath the mirror, vertical sides, and with the bottom flanged outward in a horizontal plane to form a seat on the under part of the table top as shown most clearly in Fig. 3. The top is of trapezoidal shape, as shown in Fig. 4 with. the narrower cross section at'the lifter solenoid end. The. reason for this shape is. evident from Fig. ljsince the mirror'must 'be'widei' at the most elevated portion where it intercepts the rays from B than at the portion where it intercepts the rays from A on the way to the'lens',

The lifter solenoid frame is fitted with mounting angles 85 to 38 with similar angles at the rear, referred to as 85a to respectively. This solenoid frame is supported from the chassis 25 by a sheet metal stamping 09 to which the solenoid frame is bolted using angles 81, 8 8 and 81a, 88a. This stamping 00 has cars 00, 00a, turned at the top and pierced to take the pin SI of the mirror frame hinge, with a tight fit. The pin 5} also passes through holes in thevertical sides of the mirror. frame. [0- (Fig. 3), with a loose fit, so that the pin is stationary and the 7 mirror frame turns upon it. A ball bearing could be used at this place if desired, and spacers may be used on the pin between the mirror frame and the pin supporting ears on stamping 89 to prevent the mirror frame sliding on the pin. The length of the pin is such that when the solenoid and mirror frame assembly is slipped into position and bolted to the chassis 25, there will be negligible side play of the pin and everything will be held in proper position. Around the pin between the ears as and 99a of stamping as is placed a helical spring 92 of heavy wire, with one end extended out under the horizontal part of the mirror frame, and the other extended out above the frame of the solenoid. This spring is under tension in such a manner that it tends to lift the mirror frame from horizonal. Adjustments are made such that the counterclockwise torque due to the weight of the frame and accessories, and also due to the weight of the solenoid plunger and accessories is slightly greater than the clockwise torque due to the spring, so that when the frame is released from its elevated 4.5 degree position, it will have a net counterclockwise torque at all times in its fall, and will come to rest against a stop 93 between the chassis 25 and the edge of the frame l8. In case the equipment is used where the force of gravity is less than that where the equipment is manufactured, additional weights, such as 94 may be attached to the under side of the mirror frame to make the return operation positive.

As seen especially in Fig. 3 the risers 22 and 23 by which the solenoid drives the mirror frame are located between the solenoid frame 525 and the chassis 25, and are driven by plunger. 2i using an equalizer arm S6 to which the plunger is attached by a pin ill with washer and a cotter pin to keep it in place. This connection is sufficiently loose so that the equalizer arm may rotate slightly as may be required to prevent binding. The equalizer arm may be a special. casting or fabricated from a channel section and two L sections of suitable rolled stock. The risers 22 and 23 are of rectangular section near the top, and have holes by which they are coupled to the mirror frame It by a notched casting 98 fastened by screws to the mirror frame I8, and by a hinge pin 99 suitably held in place by washers and cotter pins I88 and MI The lower ends of the risers are of circular cross section, threaded at the extreme lowest portion. These lower ends pass through vertical holes in the equalizer bar 96, and are preferably held in position by compression springs H12 between cup washers I03,

with spacers Hi4 between the upper washers and. the shoulders of the risers, and with double nuts Illti below the lower washers. These springs are to'cushion the system as the plunger 2| of" the solenoid becomes pulled into the frame, and also to permit flexible coupling from the risers to the equalizer. The spacers Hi l are of suitable length so that the mirror frame will come to the proper 45 degree angle when the plunger is pulled in, with a fine adjustment by the setting of the nuts I05. These are accessible from the narrow end of the chassis for adjustment to secure proper vertical registration of the kinescope picture on the recording surface.

To provide reduction of current in the winch ings of coil 2% of the lifter solenoid after the initial throw, strips of insulating material such as Bakelite ilil, mil and It? are mounted as shown from the angles 85, 86, 88, 85a, 86c, this from which the parts of a switching mechanism may be mounted, electrically insulated from the frame. Fixed back contacts I Iii, H811, and front contacts III, Illa are fastened to the strips Ill! and H38 respectively, and the anchorages for the movable arms are made on strip Hi9. The movable contacts HE and 5 52a are riveted into metal strips H3 and H311 normally extending horizontally, with a downward bend at the end, and the metal strips are riveted to a flexible flat spring 2I3 such as Phosphor bronze suitably shaped and secured to the insulating strip IQQ. To avoid possible confusion, the fasteners between the electrical conducting members and the Bakelite strips are not shown. Suitable electrical connections are made to the contacts and the solenoid windings from which wires lead to the controller 35 of Fig. 1.

To actuate the switch parts by the solenoid, insulating aprons H5 and H511 and driving .dogs of insulating material H5 and Elta are fastened by screws to the risers 22 and 23 as indicated so arranged that the dogs will engage the strips Iiii carrying the contacts H2 as the solenoid is pulled in part way, thus breaking the connections between contacts lit and H2, also between Illla and Ii2a. The dogs may be so shaped that one of the breaks occurs later than the other as the risers operate. The upper contacts Hi and iIIa may serve as stops although in some arrangements they could be used electrically.

The mirror frame i8 is fabricated with a portion cut away where the mirror ii? is fitted in between the bends H8 and H9, with the reflection taking place at the upper surface ofthe mirror so as to reflect light downwardly. This mirror may be fastened to the frame by cement or by metallic holding angles, not shown.

As previously indicated, the lifter solenoid and mirror frame together with all accessories may be assembled outside the chassis, and slipped into position in the chassis separate from all other assemblies.

The second assembly attached to the chassis (Fig. 2) is the shutter operating solenoid of which the frame l2! and plunger 38 may be of construction the same as in the lifter solenoid, with similar mounting angles I22 to 825 and mm to I250. inclusively. The solenoid frame is fastened to the chassis 225 by use of angles I23, I23a, and by inverted L-shaped legs I25 and iZta which are secured to angles 425, E25, and in the rear to angles I2 ia and 525a. The lever 32 is of yoked shape construction to provide two separated points of support on the pin 33 of the hinge, this pin being mounted in a hinge memher at mounted from the supporting legs I25, Ifiia. These two separate legs of the lever are spread before and behind the plunger end to which they are connected by the pin SI suitably provided with washers and a cotter pin not shown. Above the plunger, the lever arms are given two right angle bends and are riveted together, one of the arms being projected up through the chassis 25 when the assembly is in place. To reduce frictional drag, the plunger is accurately centered, and the lever arms arranged so that the plunger rises slightly during the first half Of the stroke and goes down slightly during the latter half, without binding. Also a non.- ferrous rod 2? with the right end screwed into the center of the plunger and the left end fitted to move freely in a hole in the rear of the solenoid frame-provides suflicient reduction of drag. As a result, the plunger is nearly free floating with the friction of the moving elements at 9 3|, 33', I21 so low that when deenergi'zed, the plunger is pulled out by the action of the spring built into the shutter of the lens 2% in series with the coupling spring 34.

The third assembly secured to the chassis 25 is the lens 26 mounted in a lighttight sheet metal box surrounding the upper dark chamber 2'1. The upper stamping I23 of the box is flanged down ward and has a circular hole in which is mounted the lensshutter-iris assembly 23 by means of its standard mounting nut I29. The lower stamping I30, is fianged upward and' is open for the passage of light into the lower dark chamber The upper chamber is completed by the, sheet metal envelope I3I taking the place of, the sexible bellows of folding cameras. This enveloping sheet metal is riveted to the upper and lower stampings I28 and I30, with the plane of the lower part of the stamping I30 flush with the lower part of the bent out fiangesof the chassis 25. Also the ends of the bellows I3i project downwardly below the lower stamping i 36 a slight amount. This bellows assembly with, the lens mounted thereon is mounted from the chassis 25 by pushing it up through a rectangular hole in the top part of the chassis, and securing it with screws, as shown most clearly in Fig. l. After the shutter solenoid and lens-bellows assemblies have been secured to the chassis, they are coupied together by the spring mounted to the solenoid lever by bent arm I32 and to the shutter lever by arm I33 (Fig. 4). The spring may be much stiffer than that within the shutter so thatthe stretch of the spring during operation of the lever 32 is a small amount in comparison with the motion of the shutter lever. The coupling arms I32 and I33 are such that the shutter on Instantaneous will suitably be cooked and snapped when the plunger 30 is pulledrin. An adjustable back stop I34 is suitably fastened to the chassis so that an adjustment may be made limiting the throw of the lever to be sufficient but not too greatly more than sufilcient to permit the shutterv to reset itself completely for cocking and tripping at the end of each solenoid operation. Because of different resistancevthan that of the lifter 5 solenoid, but in any event the two ends of the windings are brought out by wireswhich together with those from the lifter solenoid and switches are connected to the controller 316. v V

The fourth assembly fastened to the chassis 25 is a lower cover plate I35 of sheet metal through a hole in which the protruding ends of the bellows I3I project. This cover plate is fastened to the lower stamping I30 of the upper dark chamber assembly by means of screws, and is also suitably fastened to the flanges of the chassis. Because the lower end of the stamping I30 was set flush with the lower surface of the chassis 25, this cover plate will be flat to permit alight tight connection between the upper chamber 21 and the lower chamber 28. Screwed to the lower cover plate are guiding slides H33. and I3! with projecting lips I38 and I39, by which a removable recording chamber may be readily connected to the camera in a light proof manner. This seal may be completed by a fixed clipping slide at the far end of the slides I36 and I31, and a movable sealing clipping slide'at the front end;

Such a recording chamber may be for example detain fashioned from the recording end of a Polaroid (Land) Camera, as shown in Fig. 2 and in part in Fig. 3. For this purpose, an inner casing Hill, I iI may be placed all around the inside of the standard casing M l of such a camera, with the lower end seated on the bellows i iil, M3 and with the upper end of the inner casing turned at right angles inward. walls of the standard casing, te l may be ground down to the level of the, inner casing and a flat metal top M5 secured to the inner casing with a light proof seal all around. The thickness of the fiat top hi5 should beslightly less than that of the slide members I355, iS'i, the flat top should of course be of suitable dimension to slide into place and should have a hole in the center to admit the rays of light from the lens to the photographic recording surface. The line-up is such that the image from thes'creen AOB will properly focus, register and give proper dimensions to the image A'OB on the recording surface, such as the active surface I48 of the negativeof a Polaroid film. In the drawing, all parts below surface i 15 are standard parts of the Polaroid camera, by which the latent image may be developed and printed in a short time after exposure.

With reference to Fig. 3 it is seen how the camera as a wholemay be mounted up from below a hole in the table surface, and a removable wooden cover box it? with four sides placed around the upper part of the assembly. In this figure, the recording part of the camera is omitted, having been removed for reloading. With the Polaroid camera, the finished print may be removed from the recording chamber in thcusual manner, and it may be notedthat while one picture is being developed, another may be taken. However, we do not limit this invention to the use of this particular, method of recording, and in some respects prefer a system in which the finished picture is produced on the surface upon which the latent image is first formed.

In photography, a negative is so called in. two senses. Firstly, bright areas on the subject produce dark areas on the developed negative .and vice versa. Secondly, position transfers occur such that a reversed or mirror image is obtained.

.In the. present case the. image as seen on the active surface of the recording area is identical with the subjectasnormally viewed as regarding left and right because of the reversing effect of the mirror.. Therefore whenever the system is used. with thefinal picture produced by direct development of the latent image of the recording surface, there need be no changein the transmission of the picture as to rights and lefts. That is, the picture becomes a positiveautomatically inthe positional sense. If. the latent image is developed by the usual methods, black on the kinescope screen will be light on the. developed picture and vic versa. lhis may be corrected for by a special type of development which producesrwhite where light is impressed upon the recording surface and dark where light is not impressed. Or. if themain interest is in the recording of special transmission, the matter. of reversal. of white and black maybe taken care of by use of an added amplifier stage in the transmittercamera. e

If, however, the picture is recorded by the negative and pOsitive process, such as in usual photographyand such as in th Polaroid (Land) camera, then position compensation for the presence of the mirror mustbe used to produce a "proper picture. This may beaceomplished in a number of ways. The camera could b designed with an added mirror between the lens and recording surface, but this is not desirable from the standpoint of compactness and sensitivity. An alternaitve would be to invert the image which is being recorded, by using a mirror at the transmitter, or omitting the mirror or reflecting prism using a Belloptican projector at the transmitter, or by reversing the direction of horizontal or vertical scanning. If however the picture to be recorded must be correct on the kinescope except when recording, then th position compensation may be made by reversal of the horizontal or vertical sweep in the receiver kinescope during the recording, as described in my copending application Serial No. 129,951, filed November 29, 1949. The matters of methods of utilizing the camera to produce an acceptable picture do not constitute a part of the present invention and are discussed merely to point out that the system is not rendered inoperative by the use of a mirror, but on the contrary the use of the mirror may actually simplify the recording of pictures especially prepared and transmitted.

Having shown the general arrangement in Fig. 1 and the mechanical details of the camera itself in Figs. 2, 3, 4 now by reference to Fig. 5 on embodiment of the controller 36 of Fig. 1 is shown by which the camera may be controlled by push button 31 or by relay 44 similarl designated in both figures. In Fig. 5 the camera electrical parts are represented by the litter and shutter solenoid windings 20 and 29 respectively together with the two lifter operated switches with back contacts III), Him and moving arms H2, IIEa, the front contacts not being utilized in this arrangement. For powerizing these solenoids, an A. C.-D. C. rectifier system is provided, with the A. C. supply connected to the input terminals I48, I49, of a transformer with primary winding I50, secondary winding I5I and secondary terminals I52 and I53. A rectifier I54 of standard construction has input A. C. terminals I55, I56, the former being connected to transformer secondary terminal I52, the latter being con nected to one end of a resistor I59 and also to lifter switch contact Him. The other end of resistor I59 and the arm II2 are connected to ground line 4? which may be the same ground line as ii of Fig. 1. Therefore it is seen that the rectifier is actuated by A. 0. when the secondary terminal I53 is connected to ground, with full voltage applied when the lifter switch elements IIia and H211. are in contact and with a lesser voltage when the contacts are opened.

The manual push button 3'! comprises a support iEit through a hole in which passes an insulated rod Ifii on one end of which is the finger piece 562, with a compression spring I63 between the finger piece and the mount. On the other end of the rod III? are mounted two metallic cross pieces I64, I65, insulated from each other and there are provided four fixed contacts I66, Iii'i, I68 and I69. Normally the contacts I68 and IE9 are electrically connected through cross piece I6 and contacts I66 and I6! are isolated. When the push button is depressed against the force of the sprin I63, the contact by I66 from I68 to I69 is broken and the contact from I (iii to I61 is established by cross member 55. The normal connections become reestablished by action of spring I83 when the push button is released.

Transformer secondary terminal Iil3 is connected to manual push button terminal IE5, and

also to controller terminal 38 which in turn is connected to the front contact 84 of relay 4d, and the push button terminal I 6?, controller terminal 39 and the moving armature 8| of relay '54 are all connected to ground line 41. Therefore it is seen that when push button 3'5 is depressed or relay M is closed, the transformer secondary terminal I53 is connected to ground to complete the circuit to operate rectifier I54. Since the lifter switch elements H00. and H20: are connected for the normal horizontal position of the camera mirror, so that the A. C. line resistor I59 is shorted, full voltage will be applied to the rectifier at the start of the lifter operation and a lesser voltage toward the end of the lift after the contacts have been separated.

Negative rectifier terminal I55 is connected to the negative end of smoothing capacitor Ill] and to a terminal I'II of the lifter solenoid, the other terminal I12 of which is connected to the terminal I73 of the arm of the lifter switch with moving contact H2 and fixed back contact iIil, the latter being connected to junction terminal I14 and to the positive end of capacitor I10 and the positive end of the rectifier IE'I. Thus when at the start of the lift, the contacts II 9, H2 are closed, the lifter winding 20 is directly connected to the output terminals of the rectifier. As the lift is effected and the contacts I Iii, I I2 are separated, the voltage applied to the lifter winding 26 is reduced in accordance with the nature of the external conductive path around the contacts IIil to H2. Thus terminal H3 is connected through terminal M2 to one end of a resistor I15, the other end of which is connected to terminal I'ifi of the shutter solenoid winding 29, the other terminal I'Il of which is connected to terminal I74. In addition, terminal H3 is connected through resistor I18 to the front contact I79 of a single pole double throw relay Hit, the armature ISI of which with a terminal I82 is connected to switch terminal I13. Thus the resistor I75 is shunted by resistor I78 whenever the armature of relay IE0 is closed, as in the condition indicated.

The connections are such that no current passes through the shutter solenoid winding 2Q unless the contact between I I 0 and I I 2 is broken,-

and the rectifier powerized after closure of the relay 44 or the push button 3i. Moreover the same current passes through the two solenoids after the contact III] to H2 is broken, and this current is greater when the relay I80 is closed than when it is open.

Normally the relay I80 is closed but after the operation of the push button or relay 45, the relay will open before the lifter operates to break contacts IIIi to H2 and thus make shutter current available. This current through the shutter is insufiicient to operate the shutter mechanism, but serves to put a tension on the shutter and coupling springs so that it will very quickly trigger the shutter when the current in the shutter solenoid winding becomes suitably increased by restoring the relay I80 to the normal closed position. Thus provisions are made to be described below, whereby upon operation of the push button 3? or relay 44, the relay I88 will open and will remain open for a predetermined interval of time say 0.8 second, until the lifter has risen and come to rest, held in place by the current which passes through both shutter and lifter solenoid windings.

For this purpose, a single shot multivibrator so-called, is used utilizing two triode tubes I83 and I84. Plate power is supplied from high voltage terminal I85, connected through a resistor 13 i'8fi't'o terminalifli to which is' connected the positive end of a voltage regulator tube I83, the other end of which is connected to ground. The terminal I8? is connected through resistor I86 to the cathode of triode I83, which in turn is connected to ground 4? through resistor 89. The grid of tube use is connected through a resistor i951 to the cathode of tube W3, and also to contact ice of switch 31, the contact Hi8 of which is connected to controller terminal as and the back contact 83 of relay Mi, the armature of which is connected by terminal 39 to ground. Thus in the normal condition shown, the grid of 83 is connected to ground through contacts to the push button 3'! and the relay in series, with resistor isil'in parallel with resistor I89. The grid is therefore negatively biased. due to the current fiowing through these resistors in parallel. When either the push button is depressed breaking contacts 158 to IE or the relay 44 is thrown to break contacts es, 8 I, the grid is disconnected from ground and due to the relatively low resistance of I98 almost instantaneously comes to cathode potential.

The supply terminal it? is also connected through plate resistor IilI to the plate of triode 83, and through the winding 692 of relay ifit to the plate of triode 58%. The plate of triode P83 is connected through timing capacitor I93 to the grid of triode I85, which in turn is connected through fixed timing resistor Id l, and variable timing resistor I95 to ground line 41, to which the cathode of triode N34 is also connected.

The circuit constants are such that normally with the grid of I84 at cathode potential, there 1 is a large space current flow through winding I92. Thus for example the relay I92 may be so designed that it closes after having been previously opened when 5 milliamperes flow in the winding, and opens after having been previously closed when the current is reduced to less than 3 milliamperes, and the circuit may be so designed that normally milliamperes flow in the relay winding.

The construction is further such that normally there is little or no space current in triode I83 through the resistor IBI. As the grid of I83 suddenly increases from ground to cathode potential at the initial operation of push button 31 or relay 4G, a current rush through resistor [9| immediately depresses the potential of the plate and becaus of the slugginess of capacitor i913 across the terminals of which the voltage difference cannot immediately change, there is also an immediate depression of the potential of the grid of triode I34, which quickly cuts oil the space current of tube [84 so that the relay 580 opens due to the action of its armature spring I86. Thus the relay hit is opened even before the push button or relay stroke is completed to supply A. C. voltage to the rectifier I54, and when the lifter operates to make power available for the shutter solenoid, the shutter solenoid current is the lesser of the two possible values with the mirror fully lifted, and the shutter does not operate. However, when the voltage across capacitor I93 changes and the current flow from ground through resistors we and I94 to the capacitor has diminished suificiently, the tube 534 commences to conduct, finally passes current, then sufiicient current say 5 ma. to close the relay IN, and at the final equilibrium condition with the grid of I85 at cathode potential the tube passes and carries the normal current say 10 milliamperes. The circuit constants, adjust- 14' able by variable resistor mama be so chosen that any reasonable time may exist from the initial motion of the relay M or push button 31 to the closure of relay I'iii] after the lifter has operated, as 0.5 second to 2.0 second. I The timing of this delay action is more accurate and definite than the timing of the mirror elevation; Thus the mirror may come to rest in its final position say in .5 second with an allowance say of :2 second due to mechanical inaccuracies, amount of vibration in stopping, and irregularities in the time required to fully operate the push button 3'! or relay a l; On the other hand, the delay time for the shutter operation is quite precise, due to the presence of the regulator tube I88 which maintains fixed voltage for the ele'ctronic delay circuits, anddue to the definiteness of the time of start of the delay action. Thus an accurate system is provided for timing the receiver to catch a picture which is transmitted during a predetermined time interval.

At the release of the pushbutton 37, or of the relay id so that both are in normal position, the lifter and shuttersolenoids are deenergiaed the mechanisms are reset, the lifter by gray ity and. theshutter by spring action. There is' also a reset of the condition of the multi-vi brator tubes I83 and I 8-5 with th grid of I84 going slightly positive, limited by grid current fiow, and with a momentary increase of the relay circuit, but during this restoration the relay I continues to be closed.

Various modifications of the construction and operation or the system of camera control are possible, as will occur to those skilled in the art. For example, in Fig. i, in place of switching contacts controlled by the operation of the lifter mechanism, it is possible to decrease the solenoid voltage by substituting a grid controlled rectifier or thyratron for the fixed bridge rectiher, and to vary the grid voltage or phase in accordance with an electronic timer, thereby simplifying the mechanism within the camera. Or in the place of the first triode of the time delay circuits of Fig. 5 it is possible to substitute a transformer with phase reversing connection. Various other modifications are possible within the scope of the following claims.

What is claimed is:

1. A system for recording a still picture from a television screen, comprising a camera having a shutter and mounted in a fixed position relative to said screen, a retractible optical system having an advanced position to direct the light rays from said screen onto said camera for recording thereby and being normally retracted to a posi tion out of the path of said rays, means including a control circuit connected to advance said optical system to said advanced position, means including a control circuit connected to actuate said shutter, timed means to energize said control circuits in predetermined time sequence, means to actuate said timed means, means whereby said last named means is responsive to a predetermined received signal and means responsive to received signals other than said predetermined signal to prevent actuation of said timed means.

2. A system for recording a still picture from a television screen, comprising a camera having a shutter and mounted in a fixed position relative to said screen, a retractible optical system having an advanced position to direct the light rays from said screen onto said camera for recording thereby and being normally retracted to a position out of the path of said rays, means ineluding a control circuit connected to advance said optical system to said advanced position, means including a control circuit connected to actuate said shutter, a spring connected to actuate said shutter in response to a predetermined pull, means to exert a pull less than said predetermined pull on said spring, means whereby said last named means is responsive to energization of said first circuit and means responsive to said last circuit to increase said pull to a value to actuate said shutter.

3. A system, as set forth in claim 1, in which the optical system comprises a mirror mounted to be raised to ray-intercepting position and said first control circuit includes means to raise said mirror.

4. The system, as set forth in claim 3, in which said first control circuit includes a solenoid connected to raise said mirror to its advanced position.

5. A system for recording a still picture from a television screen, comprising a camera having a shutter and mounted in a fixed position relative to said screen, a retractible optical system having an advanced position to direct the light rays from said screen onto said camera for recording thereby and being normally retracted to a position out of the path of said rays, said optical system comprising a mirror mounted to be raised to ray-intercepting position, means including a control circuit connected to advance said optical system to said advanced position, said control circuit including a solenoid to raise said mirror to its advanced position, means including a control circuit connected to actuate said shutter, timed means to energize said control circuits in predetermined time sequence, means to actuate said timed means, means whereby said last named means is responsive to a predetermined received signal, and means responsive to received signals other than said predetermined signal to prevent actuation of said timed means.

References Cited in the file Of this patent UNITED STATES PATENTS Number Name Date 2,281,312 Krist Apr. 28, 1942 2,294,809 Smith Sept. 1, 1942 2,420,029 Brady May 6, 1947 2,429,921 Brady Oct. 28, 1947 2,489,017 Dimond Nov. 22, 1949 2,504,734 Schmidling Apr. 18, 1950 

